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Statistics on Water Point Failures

This is an ongoing compilation of statistics that shows that failure rates for water systems are still high after decades of intervention. Statistics are organized by year, starting with the most recent, and alphabetically by country.

Ghana: Of 898 wells surveyed, 20% were not operational at the time of the study (World Vision, 2014).

Ghana:”The Atebubu Water System, in the Brong Ahafo Region, served a group of eight urban communities with a total population of 32,000. The system was completely non-functional at the time of a visit—sand filters were overgrown with weeds, standpipes had been shut down, and the chlorinator appeared run down.” Many residents now obtain water from boreholes installed by the district assembly or NGOs. However, at the time of a visit 40% were broken (Ampadu-Boakye & Hebert, 2014).

Madagascar: Out of 186 communities visited, there is a very high rate of system breakdown: nearly half of all systems broke down in the previous year, and a third of them were reported not to have been fixed satisfactorily. So, by implication, one sixth (16.6%) of all rural water systems breaks down and are not properly fixed, per year. While half of all systems were reported to be functional for the most recent year, a tenth didn’t work at all; systems worked for an average of nine months per year. Note that the survey sample was of systems that had been built or rehabilitated within the last five years. So, at any one time, around a quarter of the rural population of Madagascar has no safe water (UNICEF & WaterAid, 2014).

2013

Ethiopia: A survey of 57 diverse water schemes showed 38.6% were non-functional on the day of the visit (Welle & Williams, 2014).

Ghana: 21% of 1,509 water points were not functioning on the day of visit (Samani, Destina and Patrick Apoya, Sustainable Water Service Delivery Project: Study Findings, 2013 Water and Health Conference, Chapel Hill, NC).

Malawi: In a service level survey of 48 villages, it was surprising to note that 66% of MALDA handpumps installed one year ago failed both pump tests and were therefore recorded as being non-functional. The proportion of fully functional MALDAs was between 29% and 50% in all age cohorts (Shaw & Manda, 2013).

Tanzania: national mapping shows 38% of 74,331 water points are not functional, and 7% are functional but need repair (Water Point Mapping Tanzania).

Tanzania: A survey of 43 taps and 4 cattle troughs showed that 11% were not functional on the day of the visit (Welle & Williams, 2014).

Uganda: 36% of 45 surveyed community managed well sites were not functional; another 24% were either semi-­functional needing minor repairs or minimally functional
needing major repairs (Truelove, 2013).

Uganda: In Bundibugyo, 21% of water points are not functional on average. Some subcounties have functionality rates well above 90%, but others like Kanara and Bubandi have functionality rates as low as 33%. These non-functioning systems lead to dry tap stands, resulting in about 45,000 Bundibugyo residents who are reported to be covered but in reality have to walk long distances to the nearest alternative, often an unprotected water source. Bundibugyo has registered an outbreak of either cholera or typhoid fever or both every year for the past 3 years (SNV, 2013).

Uganda: Only about 7% of 377 surveyed households reported that their village hand pumps had never failed, while the rest reported that their pumps failed nearly every month (14.5%), about twice or more in a year (54%) or once a year (15.6%). Some of the non-functional water sources were considered ‘landmarks’ by the village residents (Mugumya, 2013).

Uganda: A survey of 151 water schemes showed that 21.2% were not functional on the day of visit (Welle & Williams, 2014).

2012

DR Congo: Out of 2,051 water points in three provinces – Bas Congo, Equateur and Kinshasa – non-functionality was highest in Bas Congo at 68%, 24% in Kinshasa and 14% in Equateur (see table below). In Bas Congo only 39% of functional water points provided safe drinking water while in Kinshasa it was just 32% (Hambadiahana & Tolsma, 2012. Water Point Mapping in DR Congo) (SNV, 2013).

Percentages/Number

Province Bas Congo

Province Equateur

Province Kinshasa

Water Points

295

480

1276

Non-functional or partially functional protected water points

68%

14%

24%

Non-functional or partially functional boreholes

100%

52%

33%

Potability of protected water points

39%

NA

32%

Protected water points without management system

41%

22%

10%

Protected water points without a water payment mechanism

66%

28%

35%

Ethiopia:A survey was carried out with 160 household in 16 water supply systems constructed by different organizations. In Mecha Woreda, 20 of the 21 systems (95%) installed without community support were not functioning while only 12 of the 142 systems (8%) installed with community failed (Beyene, 2012).

Ghana: In three districts (East Gonja, Akatsi, Sunyani West), more than 30% of the surveyed infrastructure was not functional, and as little as 2% was providing the basic level of service for which it was intended (Adank et al, 2012).

Haiti:A survey of 1096 water kiosks and 2,266 water fountains showed that more than half of existing water kiosks are out of service in four geographical departments: Nord (63%), Sud (60%), Grand’Anse (59%) and Artibonite (53%) and 41.6% of existing water fountains inventoried are not functional (DINEPA, 2013).

Nepal: Of a sample of 192 water points across the country, 26% were found to be non-functional (FCG, 2013)

Sierra Leone: A comprehensive water point mapping exercise (28,845 water points) in 2012 showed the rate of damage of public water points is high and rises rapidly with point age: 14.4% were functional but partly damaged, and 17.8% are broken down. Furthermore, up to 40% of protected in-use points providing insufficient water during the dry season (Sierra Leone Ministry of Water Resources, 2012).

South Sudan: 400 of 578 boreholes built between 2006 and 2012 under the Basic Services Fund were surveyed. 23.2% of surveyed boreholes were not fully functional. The main reasons for reduced functionality were difficulties with pumping and an objectionable taste or color. The 31% of the boreholes for which no information was received were mainly the inaccessible boreholes, or the boreholes constructed by NGOs that had withdrawn from the area. These may also have been the boreholes with a higher occurrence of breakdowns or reduced functionality (Leclert, 2014).

Overall, equipment was installed as planned and was in working order. However, fewer than half of the projects examined delivered results meeting the beneficiaries’ needs.

While the projects examined were sustainable in technical terms, for a majority of projects, results and benefits will not continue to flow in the medium and long term unless non-tariff revenue is ensured; or because of institutional weaknesses (weak capacity by operators to run the equipment installed).

Swaziland: A pilot water point mapping effort in 8 Tinkhundlas (sub-districts) beginning Nov 2010 showed that out of 2,689 water points, 58.6% are functional, 11.5% are partially functional, and 29.9% are non-functional (Government of the Kingdom of Swaziland Ministry of Natural Resources & Energy, Department of Water Affairs, Water & Sanitation Point Mapping Pilot Project Report 2012).

Tanzania: One in four public kiosks were not functional at the time of an interview of 324 residents of Dar es Salaam (Listening to Dar, 2012).

Uganda: 19% of 79,413 water points are not working. Shallow wells have the highest non-functionality rates (approximately 30%), while protected springs have the lowest non-functionality rate (approximately 88%). As many as 2,303 point water sources (2.9%) are considered abandoned, having been non-functional for five or more years (Nekesa & Kulanyi, 2012).

Uganda: On average, close to 70% of all households surveyed in all the eight districts access low or substandard water services (Triple-S, 2014).

2011

Belarus: 14.5% of rural water supply systems do not meet microbial quality standards and 30.1% do not meet chemical standards (WHO, 2011).

Central African Republic: only 10% of the wells and boreholes provide safe water despite these being the main source of water for urban dwellers (Dominguez-Torres and Foster, 2011).

Dominican Republic: A sustainability assessment of 61 rural water systems found that 18% are unlikely to be sustainable (it is unlikely the community will be able to overcome significant challenges) (Schweitzer & Mihelcic, 2012).

Ethiopia: 25.5% of more than 93,000 water schemes across the country were non-functional according to the National Water Inventory (Debela, 2013)

Ethiopia: Of 91 water schemes in Farta and West Estie surveyed, 17.5% were not functioning and 10% were functioning with difficulties (Stawicki, 2012).

Kenya: Of 100 water systems assessed (built between 2006-2010), 75% are still in use. 45% are affected by minor technical issues, or even serious damages, although they have the potential to be remediated. 14% of the systems are non-functional (Welthungerlife, 2011).

Liberia: The first systematic sampling of water points and study of water quality in Monrovia found that 57% of the water points were contaminated by E. coli, which is an indicator of widespread fecal contamination. The health standard for E. coli is none present/detected. (How a City Gets its Drinking Water: A Case Study – Capital City of Monrovia, Liberia, Vincent W. Uhl, Ashish Daw and Jaclyn A. Baron, 2012)

100% of the unprotected hand-dug wells sampled showed the presence of E. coli.

75% of the kiosks sampled showed the presence of E. coli.

67% of the LWSC city water taps sampled showed the presence of E. coli.

52% of the protected hand-dug open wells fitted with hand pumps showed the presence of E. coli.

44% of the drilled wells fitted with hand pumps showed the presence of E. coli.

Malawi: A survey of the water schemes in the early 1980s showed over 90% of taps were functioning, but now only 42.4% are functioning: in the Northern Region, 74% of 2305 taps from gravity-fed piped water schemes are non-functional; in the Central (1,465 taps) and Southern Regions (10,215 taps), 55% of the taps from piped water systems are non-functional (Ministry of Agriculture, Irrigation, Water and Development, 2011).

Mali: in four municipalities, non-functionality of “modern” water points ranged from 14 to 41% (Jones, 2013).

Rwanda: In a baseline survey of 126 water points in the District of Kicukiro, 50% of the water points had been down for more than 1 day in the last month, and 55% of the communities reported that they had no spare parts on hand for the water system (Water for People 2011).

Madagascar: Functionality of existing water points is 90% for boreholes according to a 2009 RWSN report; 20% according to a 2010 baseline survey of the USAID-funded RANO HamPivoatra Project. Actual functionality rate is likely between 40 – 50% nationally (Annis, 2013).

only 43% of community based organizations responsible for subprojects are functional and their capacity remains weak.

Sierra Leone: A survey of all existing water access points across three districts (2,859 structures) found only 30% of the structures in place were found to be capable of delivering access to safe water throughout the year (Fondation Pro Victimis).

Uganda: 19% of water points across the country are non-functional based on the national water supply atlas (MWE, 2010).

Nepal: A national survey of households in 36,038 wards found only 18% of the population with a water supply are served by well functioning water points/ systems; 39% are served by points that need minor repair, 12% by points that need major repair, 21% by points that need rehabilitation, 9% by points that need reconstruction, and 1.6% by points that cannot be rehabilitated (NMIP, 2011).

Tanzania: Mapping 55 of the 132 district showed that 43% of the water points were no longer working, and that 25% of the water schemes had become non-functional within two years of installation (SNV World, 2014).

Timor-Leste: An assessment of all (134) rural water supply systems in Covalima district found: of 54 piped systems, 44% were fully functional, 30% partially functional, and 26% not functioning. Of the 80 hand pumps, 11 were under construction, 41% of completed systems were fully functional and 59% not functioning (Oxfam, 2008).

2007

Bolivia: in over 100 communities visited in the rural municipality of Tiraque, fewer than ten had no water system, 17 were functioning per Bolivia government norms, and the rest were providing sub-par services, requiring anywhere from complete rehabilitations to minor repairs to ensure water of adequate quantity, quality, and continuity was being provided to all citizens (Fogelberg, 2013).

Ethiopia: It has been estimated that 33% of rural water supply schemes are non-functional at any time (MoWR, 2007) (per Deneke & Abebe, 2008).

Ethiopia: 60% of the Somali region’s birkado [cement-lined underground cisterns] are damaged and unused, calling into question the building of new birkado versus rehabilitating existing structures (Nassef & Belayhun, 2012).

Germany: In Baden-Württemberg, 523 samples from approximately 13,500 private wells were analyzed in 2007; non-compliance rates for E. coli (an indicator of fecal contamination) and total coliforms were at 18% and 43%, respectively (WHO, 2011).

Macedonia: Local piped water supply systems, used by 54% of the rural population, had a bacteriological failure rate of 23%. Local (non-piped) water sources, used by 13% of the population had a bacteriological failure rate of 30% (WHO, 2011).

Malawi: 49% of all gravity flow system taps were not working (National Water Point Mapping, reported in Bauman & Danert, 2008)

South Africa: In a sample of water and sanitation projects in all nine provinces, the compliance level for 1067 completed household water projects was only 2.6% – more than 97% of the projects did not comply with policy requirements, norms and standards. The compliance level for 517 completed household sanitation projects was 0% – that is, none of the completed household sanitation projects complied with policy requirements, norms and standards (CSIR, 2007).

Sub-Saharan Africa: Figures collated by the Rural Water Supply Network in 2007 indicate an average rate of 36% non-functionality for hand pumps across 21 countries. This level of failure represents a total investment of between $1.2 and $1.5 billion in the last 20 years. (Triple-S, 2009)

2007

Haiti: In Port-de-Paix there were no functioning public water sources in the city and 14 of 19 different sites throughout the city that investigators tested for water quality were bacterially contaminated (Center for Human Rights & Global Justice, 2007).

South Sudan: The Water Policy (2007) indicated that 30-50% of the water points are non-operational at any time in the different States (Leclert, 2014).

2006

Ethiopia: A survey found that 29% of handpumps and 33% of mechanized boreholes in rural areas were not functioning because of maintenance problems. (UNDP, 2006)

2004

Ecuador: a sustainability studyconducted by the Secretariat forWaterfound that13% of the systems were sustainable, 29% had mild problems, 20% had severe problems, and 38% were broken down (mentioned in OAS).

India: 25% of India’s water infrastructure is believed to be in need of repair (Ray, I., 2004, “Water for all? Peri-urban and rural water delivery options: The case of India.” Presentation: UC Berkeley Energy and Resources Group Fall Colloquium Series, 6 October).

2003

England & Wales: An analysis of data collected from 150 local water authorities covering approximately 35,000 microbial water quality results for approximately 11,200 private water supply sites from 1996–2003 showed that E. coli (an indicator of fecal contamination) was detected in 19% of samples, with at least one positive sample being detected at 32% of water supply sites (compared to 0.1% of samples from mains water supplies) (WHO, 2011).

Peru: In a study of 104 rural water systems, only 32% were deemed “sustainable”; 66% were deteriorated and 2% were broken down (WSP, 2003).

South Africa: At any time, approximately 50% of handpumps are not working (Hazelton, 2000).

1999

Czech Republic: Water quality data from approximately 1700 small public groundwater well supplies and 3300 private wells from the period 1991–1998 showed there was a non-compliance rate with health-related parameters of approximately 70% (WHO, 2011).

1998

Scotland: Out of 1750 samples taken from private water supplies in Scotland between 1992 and 1998, 41% failed compliance for total coliforms, 30% failed for E. coli and 15% failed for nitrate. The combined failure rate was 48% (WHO, 2011).

1997

Malawi: In 1997, a survey almost 900 tapstands found that more than 50% of them were not supplying water. This indicated a significant decline since the early 1980s when surveys showed fewer than 10% not functioning (Kleemeier, 2000).

1990

Ghana:By the late 1980s and early 1990s, 33% of the water supply systems had deteriorated greatly or completely broken down due to inadequate funding to carry out maintenance and rehabilitation (Ghana Water Company).

1989

India: Evaluation of a representative sample of 10 water points found that consumers are not receiving protected water of the required quality in any scheme evaluated (Somayajulu, B.V.S., and Rao, Y.R., 1990)

1981

(USAID, 1981. The Role of Women as Participants & Beneficiaries in Water Supply & Sanitation Programs)

1980

Uganda: In 1980, UNICEF funded a national inventory of boreholes and found that, out of a national stock of 5,089, 75% were not working. An extensive rehabilitation program was undertaken, but three years later the percentage of non-working pumps had only decreased to 67.8% (IRC, 1993).

1974

India: UNICEF assisted the Government of India with water access by drilling thousands of wells starting in 1967 when a severe drought hit several states in India. Approximately 75% of the installed cast iron pumps were not working in 1974, just seven years later (Mudgal, 1997).

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13 thoughts on “Statistics on Water Point Failures”

I am very sad to read these figures.I am presently leding a project in Western Nepal and have attempted to secure its future by appointing a committee of local people to oversee the maintenance of plant etc when finished.I feel it is essential to have as much local input as possible.

These reasons are good. But there are also factors such as:
1) lack of sustainability of the aquifer (depletion of water levels on account of over exploitation of under ground water) There should be simultaneous and proper ongoing recharging of the underground water resources in absence of which the soil structure changes leading to its lessened water holding capacity next time the rain water goes down.
2) Alienation from the project (Beneficiaries don’t get much involved much in the responsibility of maintenance).

Good work though I would suggest the article takes official statistics in Malawi. For example, water point functionality in December 2013 was at 75 percent as reported by Sector Performance Report (GoM, 2013)